A semiconductor pressure sensor includes: a first silicon substrate including a first recessed part; and a second silicon substrate including a diaphragm covering a first space in the first recessed part, the second silicon substrate being configured to hermetically seal the first space. In cross-section, a plurality of second spaces are hermetically sealed in a state of being separated away from the first space between the first silicon substrate and the second silicon substrate, and are provided in one of or each of a first end side and a second end side of the first space.

A method of fabricating a plurality of individual microelectromechanical transducer elements includes forming a plurality of microelectromechanical transducer elements on a wafer. Each microelectromechanical transducer element has a sensitive region with a membrane and a sensing element monitoring at least one measurand and generating an electrical signal correlated with the at least one measurand, and an electrical contact outputting the electrical signal. The method includes providing, for each microelectromechanical transducer element, a sealing structure around a sensitive region and an electrical connection connected to the electrical contact. The sealing structure and the electrical connection are made out of a reflow solder material. The method includes dicing the wafer to form individual microelectromechanical transducer elements.

A ceramic substrate is mainly constituted of ceramic, and has a first main surface and a second main surface located opposite to the first main surface. A recessed portion recessed toward a first main surface side is formed in the second main surface. A wire portion extending from an outer peripheral surface of the ceramic substrate to inside of the recessed portion is formed, and a bottom portion located on the first main surface side in the recessed portion has a portion thinner than another portion of the ceramic substrate other than the bottom portion.

Provided are a capacitive transducer that can make a sealing film thickness necessary to seal a gap smaller and can enhance performance such as a wider bandwidth, and a method of manufacturing the capacitive transducer. The capacitive transducer including cells each including a vibration film including a second electrode that is provided with a gap from a first electrode can be manufactured in the following manufacturing method. A convex part is formed on the first electrode, a sacrifice layer having a thickness larger than the thickness of the convex part is formed on the first electrode and the convex part, and a membrane is formed on the sacrifice layer. Further, an etching hole is formed in the membrane at a position above the convex part, the sacrifice layer is etched through the etching hole, and the etching hole is sealed by a sealing layer.

A semiconductor pressure sensor device in which the shape or the structure of a connector portion can be easily changed and which has high waterproof performance. A terminal housing and a second case are engaged with each other via an engagement structure. The terminal housing and a first case are fitted with each other via a fitting structure. Thus, the first case and the second case are fixed to each other via the terminal housing. The first case is fitted in the second case. Then, the terminal housing is fitted with the first case, and the terminal housing is engaged with the second case substantially at the same time. Through such simple process, an opening portion of the first case is covered and a connector portion configured to enable external terminals to be connected to ends, located on one side, of a plurality of lead terminals is formed.

An electrical component package includes a glass substrate, an interposer panel positioned on the glass substrate, the interposer panel comprising a device cavity, a wafer positioned on the interposer panel such that the device cavity is enclosed by the glass substrate, the interposer panel, and the wafer. The electrical component package further includes a metal seed layer disposed between the interposer panel and the wafer, and a dielectric coating. The dielectric coating hermetically seals the interposer panel to the glass substrate, the interposer panel to the metal seed layer and the wafer, and the interposer panel hermetically seals the metal seed layer to the glass substrate such that the device cavity is hermetically sealed from ambient atmosphere.

A microelectromechanical system (MEMS) device may include a MEMS structure above a first substrate. The MEMS structure comprising a central static element, a movable element, and an outer static element. A portion of bonding material between the central static element and the first substrate. A second substrate above the MEMS structure, with a portion of a dielectric layer between the central static element and the second substrate. A supporting post comprises the portion of bonding material, the central static element, and the portion of dielectric material.

An apparatus includes a substrate having at least one via disposed in the substrate, wherein the substrate includes a trench having a substantially trapezoidal cross-section, the trench extending through the substrate between a lower surface of the substrate and an upper surface of the substrate, wherein the top of the trench opens to a top opening, and the bottom of the trench opens to a bottom opening, the top opening being larger than the bottom opening. The apparatus can include a mouth surrounding the top opening and extending between the upper surface and the top opening, wherein a mouth opening in the upper surface is larger than the top opening of the trench, wherein the via includes a dielectric layer disposed on an inside surface of a trench. The apparatus includes and a disposed in the trench, with the dielectric layer sandwiched between the fill and the substrate.

A flow through Micro-Electromechanical Systems (MEMS) package and methods of operating a MEMS packaged using the same are provided. Generally, the package includes a cavity in which the MEMS is enclosed, an inlet through which a fluid is introduced to the cavity during operation of the MEMS and an outlet through which the fluid is removed during operation of the MEMS, wherein the package includes features that promote laminar flow of the fluid across the MEMS. The package and method are particularly useful in packaging spatial light modulators including a reflective surface and adapted to reflect and modulate a light beam incident thereon. Other embodiments are also provided.

A MEMS device package assembly for encapsulating one or more internal components includes a first MEMS device package. The first package includes a cover and a substrate attached to the cover by any suitable methods of attachment. A corrugated structure is formed on at least one of an inner or outer wall of the cover. The assembly further includes a second MEMS device package having a cover, a substrate, and a corrugated structured formed on at least one of an inner or outer wall of the cover. The first and second MEMS device packages may be coupled to the same substrate or different substrate. In another embodiment, the first MEMS device package may be mounted on the second MEMS device package. In yet another embodiment, the first MEMS device package may be contained in the second MEMS device package.